Apparatus for simultaneously blow molding and compression molding plastic containers



Oct. 20, 1970 F. w. JOHN 3,534,435

APPARATUS FOR SIMULTANEOUSLY BLOW MOLDING AND COMPRESSION MOLDING PLASTIC CONTAINERS Original Filed Aug. 5, 1965 5 Sheets-Sheet 1 PRIOR ART FIG] 5)] HUMAN I L f V Hm 0 i! 2 FREDERICK W JOHN 83 B omc i /fl i i Y A W5 ATTORNEYS Oct. 20, 1970 F. w. JOHN 3,534,435

APPARATUS FOR SIMULTANEOUSLY BLOW MOLDING AND COMPRESSION MOLDING PLASTIC CONTAINERS Original Filed Aug. 5, 1965 5 Sheets-Sheet 3 Oct. 20, 1970 PRESSURE CONTROL SYSTEM BLOW FIG.IO

F. W. JOHN APPARATUS FOR SIMULTANEOUSLY BLOW MOLDING AND COMPRESSION MOLDING PLASTIC CONTAINERS Original Filed Aug. 3, 1965 5 Sheets-Sheet 3 Hen INVENTOR FREDERICK w. JOHN ozf qc 5 ATTORNEYS Oct. 20, 1970, JOHN 3,534,435

APPARATUS FOR SIMULTANEOU BLOW MOLDING AND IC CONTA COMPRESSION MOLDING PL INERS Original Filed Aug. 3. 1965 5 Sheets-Sheet 4.

/ l l 7 x l i 2PM" A I e9 I a 67 INVENTOR v FREDERICK w. JOHN w 85 mmw ATTORNEYS Oct. 20,1970 3,534,435

APPARATUS FOR SIMULTANEOUSLY BLOW MOLDING AND COMPRESSION MOLDING PLASTIC CONTAINERS Original Filed Aug. 3, 1.965 5 Sheets-Sheet 5 INVENTOR FREDERICK w. JOHN BY dig/51C ATTORNEYS United States Patent Otfice Patented Oct. 20, 1970 3,534,435 APPARATUS FOR SIMULTANEOUSLY BLOW MOLDING AND COMPRESSION MOLDING PLASTIC CONTAINERS Frederick W. John, Rochester, N.Y., assignor to Sybron Corporation, a corporation of New York Original application Aug. 3, 1965, Ser. No. 477,692, now Patent No. 3,398,427, dated Aug. 27, 1968. Divided and this application Apr. 8, 1968, Ser. No. 719,780

Int. Cl. B29c 17/07; B29d 23/03 US. Cl. 18-5 7 Claims ABSTRACT OF THE DISCLOSURE There is disclosed herein an improved plastic liquid container together with method and apparatus for manu facturing the same. The container is characterized by unitary blow molded construction and has among its features an integral blow-molded discharge tube, and preferably also an integral compression molded removable closure. The apparatus includes a mold and a molding machine with the mold being characterized by two engageable mold sections each having one or more cavities of proper configuration to form the container and a compression molding die portion to form the closure. The mold is constructed according to certain dimensional relationships so as to produce an operative and commercially acceptable product. Suitable dimensional relationships are maintained between the mold and the remainder of the molding machine for like purposes. Also characteristic of the machine is the facility to control blowing pressure in relation to degree of mold closure. The method of this invention is characterized by the concurrent blow molding of the container and discharge tube and compression molding of the various container portions and by control of the degree and times of pressurization in relation to the degree of mold closure to produce a properly formed container.

This invention relates to apparatus for the blow molding of a plastic liquid container dispenser, such as a laboratory wash bottle, reagent dispenser, or the like, having a plastic discharge tube integrally molded therewith, and also having a cap integrally molded therewith when desired.

This application is a divisional application of copending application Ser. No. 477,692, filed Aug. 3, 1965, now Pat. No. 3,398,427.

A wide variety of liquid dispensing containers are in use which have attached thereto various spouts or other tubes for discharging or receiving liquids. Typically, in the manufacture of such liquid dispensers, the container and the discharge tube are separately fabricated, after which the parts are assembled to produce the finished article.

It has been the standard procedure in the fabrication of plastic laboratory wash bottles or other similar plastic liquid dispenser to fabricate the bottles or container portion by various well known blow molding techniques and to later attach a suitable length of plastic tubing to provide a discharge means. In such laboratory wash bottles, it is desirable that the discharge tube have its upper end bent into a downwardly depending spout for convenient use. Since the discharge is provided by compression of the flexible walls of the bottle, it is further desirable that the discharge tube extend nearly to the bottom of the bottle, to minimize the amount of fluid which cannot be expelled; however, the tube should not rest on the bottom of the bottle or the supply of fluid may be cut off. An additional requirement for such a bottle is that it be conveniently fitted with a suitable closure for its filling opening both to prevent spilling or contamination of the contents and to prevent excessive pressure relief when the bottle walls are compressed.

In previous wash bottles, after the container portion has been fabricated by blow molding, an opening is made in the upper end thereof and a suitable length of plastic tubing, bent to provide the discharge spout, is inserted. While such bottles have enjoyed substantial commercial success (applicants employer being a major producer of the same), such prior wash bottles and liquid dispensers entail certain disadvantages due to their construction and the fabricating technique outlined above.

In particular, because it is necessary to produce the wash bottle in multiple separate stages, the process is time consuming and as a result, quite expensive. In addition, with the prior construction, the opening provided in the bottle for insertion of the discharge tube must be very accurately made since if it is too large, the discharge tube will drop to the bottom of the bottle cutting off he fluid supply, or else liquid will leak from around the tube. On the other hand, if the opening is made too small, the tube will be difficult to insert, and attempts to insert it in an opening of too small a size may result in cracking of the container wall.

Also, the closure for such bottles has been produced separately heretofore, resulting in a further increase in equipment, production time and costs.

It is accordingly an object of this invention to provide novel apparatus for blow molding a plastic wash bottle or like container having a concurrently blow molded discharge tube. It is a related object to provide a novel apparatus for blow molding a complete laboratory wash bottle or the like which does not leak or have other shortcomings of prior wash bottle constructions (and like containers).

It is another important object of this invention to provide novel apparatus for fabricating a blow molded plastic wash bottle or the like in such manner as to more efiiciently utilize the plastic material than heretofore possible.

It is a related object of this invention to provide novel apparatus for drastically reducing the cost of laboratory wash bottles and the like, by novel apparatus and improved utilization of the starting material.

It is a further object of this invention to provide novel apparatus for simultaneously fabricating an improved blow molded plastic bottle with a simultaneously compression-molded integral cap. It is another related object of this invention to provide novel improved apparatus for blow molding plastic wash bottles and like containers with a simultaneously compression molded integral cap connected to the bottle by a strap.

The present invention accomplishes the above-enumerated objects by simultaneous blow molding of the container and a suitably shaped and positioned discharge tube. Particular features of the present invention include a sec tional mold of novel configuration, by which the container and its discharge means may be simultaneously blow molded, and which may be readily adapted to include 3 means for the concurrent compression molding of a cap or other closure means.

Another feature of the present invention resides in the particular arrangement of the blow molding apparatus whereby a bottle possessing high strength and quality may be produced using a minimum of starting material. Further features of the present invention reside in the utilization of a novel improved fabrication technique achieving advantages from particular positioning of the molding material with respect to the mold, and in the provision of suitable pre-blow conditions during assembly of the mold around the molding material (parison) prior to actual blow molding of the bottle, etc.

The exact nature of the present invention, and other objects, advantages and features thereof will be readily apparent from consideration of the following specification with reference to the annexed drawings in which:

FIG. 1 is a vertical partly sectional view of the blow molding apparatus of this invention showing the relation of the extruding head and blow pin and part of the parison to one of the blow mold sections;

FIG. 2 is a bottom plan view of the blow mold section of FIG. 1 (looking in the direction of arrows 22 in FIG. 1);

FIG. 3 is a top plan view of the blow mold section of FIG. 1 (looking in the direction of arrows 33 in FIG. 1);

FIG. 4 is a cross sectional view of one of the blow mold sections, taken along line 44 in FIG. 1;

FIG. 4A is an enlarged view showing a preferred construction of a portion of FIG. 4;

FIG. 5 is a bottom plan view of the blow molding apparatus of the invention as partially illustrated at FIG. 1 showing two halves of the blow mold, in a double mold arrangement whereby a plurality of bottles may be simultaneously blow molded;

FIG. 6 is a side elevation view of the unitary blow molded wash bottle of this invention, with a cutaway portion of the main bottle portion to show part of the discharge tube in section;

FIG. 7 is a horizontal cross sectional view of the bottle and discharge tube taken along line 7-7 in FIG. 6;

FIG. 8 is a top plan view of the bottle and tube of FIG. 6;

FIG. 9 is a horizontal cross sectional view of the two mold sections of the invention in their open position and of an extruded parison illustrating the eccentric relation of the parison to the mold sections and the blow P FIG. 10 is a horizontal cross section view like that of FIG. 9 but showing the two mold sections in a partially closed position and illustrating partial deformation of the parison;

FIG. 11 is a cross sectional view of the mold in its closed position, and illustrating deformation of the blow molded parison (but before completely blowing the main bottle portion);

FIG. 12 is a side elevation view of a modified embodiment of the invention showing a blow mold section (similar to that of FIG. 1) combined with a compression molding core;

FIG. 13 is a side elevation view relating to the embodiment of FIG. 12, showing part of the complementary blow mold section and compression molding die used with the mold section shown 'in FIG. 12;

FIG. 14 is a cross section view of the two mold sections of this embodiment in their closed position taken along line 14--14 in FIGS. 12 and 13;

FIG. 15 illustrates a blow molded wash bottle having an integral cap produced by the new method using the apparatus of FIGS. 12 through 14;

FIGS. 16 and 17 are illustrations of the relationship of the extruding head, mold, blow pin, and parison in accordance with this invention; and

FIG. 18 is an illustration of a typical prior art wash bottle.

Referring first to FIG. 18, for background, there is shown an example of commercially available plastic wash bottles made by techniques heretofore employed. Such a wash bottle typically comprises a blow-molded container portion 1 having a boss 2 at the upper end thereof which is drilled to provide aperture 2' through which a suitably bent discharge tube 3 may be inserted. As previously indicated, this wash bottle construction such as shown in FIG. 18, which has been used many years, entails a number of long recognized difiiculties and disadvantages from the viewpoints of production, reliability and cost, resulting from the necessity of preparing and inserting the bent tube 3 in the carefully positioned and sized opening 2 in boss 2.

In contrast, the unitary blow molded wash bottle 4 of the present invention, shown in FIGS. 6 through 8, comprises a main container or body portion 5 and an integral discharge tube portion 6. As shown in FIGS. 6 and 7, main bottle wall 8 is pinched and welded at web 9 to form a longitudinal passage 10 through the discharge tube portion. As shown in FIG. 6, discharge passage 10 is in communication with the inside of main container portion 5 of bottle 4 through an opening indicated at 11, since the pinched web portion 9 forming discharge tube 6 extends only to a predetermined point 12 slightly above the bottom of main container portion 5. In addition, discharge tube 6 includes 3. simultaneously blow molded downwardly depending spout portion 13, the particular configuration of which is designed to suit the contemplated use of the bottle (e.g. as laboratory wash bottle, squeeze-spray bottle, etc.). For a laboratory wash bottle, a separately molded tapered tip 14 may be provided on the end section 13' of spout 13 which is molded to suitable design for this purpose. In addition, bottle 4 generally includes a neck portion 15, having a suitably shaped lip 16. The container portion 5 and discharge tube 6 of novel unitary bottle 4 are simultaneously blow molded, as will now be described.

In order to produce the bottle shown in FIGS. 6 through 8, molding apparatus such as shown in FIGS. 1 through 4 may be used. FIG. 1 shows the general construction and arrangement of novel blow molding apparatus according to the present invention, a number of nonessential features having been eliminated to facilitate a clearer showing and explanation. The apparatus comprises a conventional extruding head such as shown at 20, a novel two piece blow mold having two complementary like sections such as shown at 21, and a suitable blowing mechanism such as a calibrated blow pin 22.

As illustrated, extruding head 20 comprises a body portion 23, having a die section with longitudinal bore 24, and sealed at its upper end by a plug 25. Suitably supported, as by plug 25, is a mandrel or core 26 coaxial with the longitudinal bore 24 of such diameter as to provide a land section with an annular extruding passage 27 having a suitable annular dimension for the desired wall thickness of the parison to be extruded from head 20. A passage 28 is provided in communication with bore 24 so that plasticated plastic material may be supplied to extruding annulus 27 in any convenient known manner, as by an extruder. As the plasticated plastic material (e.g. polyethylene) passes from the end of annular extruding passage 27, it forms the plastic parison 29 from which the bottle will be blow molded.

As the parison 29 is formed by the extruding annulus 27, it extends downward between the opposed mold like sections 21 and 21a (see FIGS. 9-11) until a sufficient length of parison has been extruded from which to blow mold the bottle. (This would be a small distance beyond the lower edge 21' of mold section 21.)

As shown in FIGS. 1 and 9-11, each of mating mold sections 21 and 21a comprises a recessed portion 30 corresponding in shape to that of the bottle to be blown.

The outer side edges of recess 30 are defined by longitudinally extending raised lands 31 and 31' which coact with corresponding lands on the other mold half section 21a to seal the sides of the mold cavity (see FIG. 11) in conjunction with lands 32 on each of mold sections 21 and 21a, defining the bottom of the bottle cavity. Bottom lands 32 serve to pinch off the part of parison 29 which is to be blown into a bottle from the upper portion of the parison 29 adjacent extruding head 20 and also to seal the upper end of the tubular parison disposed within the mold to enable expansion thereof to fill the mold cavity 30 when the bottle is blown. An additional land 33 extends longitudinally of each of mold sections 21 and 21a to a point adjacent bottom land 32 and spaced a small distance from side land 30 thus forming a pinched off area which separates the container portion of the blow molded bottle 4 from the unitary discharge tube 6. Cavity 30 of each of mold sections 21 and 21a is provided with a region of reduced transverse dimension 34 terminating in a neck plate 34 corresponding in shape to that of neck for the blow molded bottle 4 (see FIGS. 1, 2 and 6). Neck forming mold portion 34 also is provided with a further recessed groove 35 defining the lip 16 of the blow molded bottle 4.

The blow molding arrangement illustrated in FIG. 1, with extruder head above mold sections 21 and 21a, and blow pin 22 below the mold sections for entry into downwardly disposed mold neck forming portion 34 is representative of the arrangement for use of the present invention on a Kautex type plastic blow molding machine such as made and sold by Kautex-Werke, Reinold Hagen, Hangelar Siegburg, Germany.

Alternatively, the inventive concepts disclosed herein are readily adaptable for use with other commercially available blow molding apparatus such as the type shown in US. Pat. No. 3,120,679 which, while directed to substantially different subject matter, shows another commercially available molding apparatus having the extruding die and blow pin combined into a unitary element or blow head. The manner of use of such alternative apparatus to practice the present invention will be apparent to those skilled in the art in light of the disclosure herein, whereby further detailed discussion thereof is deemed unnecessary.

Referring still to FIG. 1, the blowing mechanism, i.e., blow pin 22, shown in blowing osition, comprises a body portion 37 having therein an air passage 38 which is connected to a suitable compressed air source in known manner. Body portion 37 includes a generally cylindrical portion 39 which cooperates with recess and neck plate 34' on the mold sections to form bottle lip 16 (see FIG. 6). The blow pin also includes an upper portion 39, shown having a generally tapered configuration beginning in the region adjacent recess 35, although it should be understood that a cylindrical configuration, (or any other operative configuration) may be employed. When the two mold sections 21 and 21a are fully closed, blow pin portion 39 is fully inserted in the neck forming opening defined by mating portions 34 of the two mold sections 20 and 20a, and a seal is provided at the lower end of the mold cavity by pinching off part of the parison 29 between blow pin part 39 and neck forming mold portions 34 and 35.

Thereupon, the introduction of compressed air (or other suitable pressurized fluid) through blow pin passage 38 will cause the semi-fluid parison to expand into conformity with the walls of the cavity formed by the interior of two closed mold sections 21 and 21a, as amplified below, while blow pin portion 39' and the mating mold neck portions 34 in effect compression mold the neck 15 of bottle 4 (shown in FIG. 6).

Further details of the construction of the novel blow molding apparatus according to this invention may be understood by reference to FIGS. 2 through 4, in conjunction with FIG. 1. FIG. 2 which is a bottom plan view of the mold section 21 of FIG. 1, shows the land 32 at the upper end of the mold (see also FIGS. 1 and 3), the reduced diameter neck forming portion 34 of land 31, and the lip forming recess 35. As disclosed, each of mold sections 21 and 21a includes a groove 42 extending longitudinally of the mold body as shown in FIG. 1 and having a cross sectional shape as shown in FIGS. 2-4 and 9-11. There is disposed in groove 42 an alloy tool steel insert 43 of cross sectional shape shown in FIGS. 24 and 9-11, and having a plan configuration as shown in FIG. 1, from which it will be apparent that insert 43 forms a land 33 and a substantial part of side land 31' (for about the same longitudinal extent as land 33) merging into bottom land 32. (See FIG. 1). Each insert 43 is retained in groove 42 of mold sections 21 and 21a respectively by a plurality of cap screws extending through apertures 82 in the main body of each of mold sections 21 and 21a, and secured in threaded apertures 84 in inserts 43. (See FIGS. 1, 2 and 4.) Each of mating mold inserts 43 is provided with a groove 86 of arcuate shape as shown in FIG. 1 and substantially semi-circular cross section, and bounded by conventionally relieved pinching lands 87, 88 and 89 (merging with land 31), to form the spout portion 13-13 extending downwardly from discharge tube 6 of blow molded wash bottle 4 (see FIG. 6). Referring to FIGS. 2, 4 and 9-11, the thickness of insert 43 is less than the depth of groove 42 in each of mold sections 21 and 21a a sufficient amount to provide a flash relief depression 44 to accommodate excess material from the blow molded plastic parison 29.

To provide accurate alignment between complementary mold sections 21 and 21a, pins 45 may be provided on one of the mold sections 21 for fitting into a complementary bushing 45 in the other mold section 21a.

FIG. 3 shows a top plan view of mold section 21, and illustrates that each of the mold sections 21 and 21a is usually provided with suitable heat exchanging means, such as the bores 48 shown in communication with coolant passages 49, in a manner known in the art. Each of mold sections 21 and 21a is also usually provided with a mounting plate 83 for mounting on the usual mold platens of the aforementioned commercially available machines for opening and closing the mold comprising sections 21 and 21a in relation to extrusion of the parison and operation of the blowing apparatus such as blow pin 22, in a manner which will be apparent to those skilled in the art in light of the disclosure herein.

Referring to the sectional views of FIGS. 4 and 9-11, side land 31 of each mold section 21 and 21a is machined and relieved per conventional practice to provide a clean bottle edge opposite the bottle discharge tube, since proper positioning of the mating mold sections 21 and 21a with respect to the extruding head 20 as explained below will eliminate the necessity of trimming this edge of the finished blow molded liquid dispensing bottle 4. However, a groove 51 of suitable width and depth extends longitudinally alongside land 31 for flash relief, if that should prove necessary by failure to follow procedures hereafter discussed. Still referring especially to FIGS. 4 and 9-11, the other bottle cavity side land 31' formed in the alloy tool steel insert 43 of each of mold sections 21 and 21a is designed and machined so that the mating lands 31 will cleanly pinch off excess parison when the mold sections 21 and 21a are closed, as shown in FIG. 11 and further discussed below. Land 31 formed in alloy tool steel insert 43 preferably has a cross sectional construction with angular reliefs as shown at 92 and 94 in the FIG. 4A enlarged segment of FIG. 4 to effectively accomplish the above-stated functions and results.

However, referring particularly to FIGS. 1, 4, and 9-11, previously described lands 33 extending alongside land 31' on mold sections 21 and 21a do not meet when the mold sections are closed (as in FIG. 11). Instead, the edge of each of lands 33 extends short of the plane of abutting lands 31, 32, 31 (when dies 21 and 21a close,

per FIG. 11) for a minimum distance substantially equal to at least one-half /2) the minimum feasible thickness of web 9 for satisfactorily joining discharge tube 6 to the main portion of a unitary blow molded wash bottle 4 or like liquid dispenser. Also, matching lands 33 stop short of bottom lands 32 a sufiicient distance, indicated at 90 in FIG. 1, so as to provide an adequate size opening 11 in communication with passage 10 in integral discharge tube 6. Preferably discharge tube forming lands 33 terminate short of bottom cavity lands 32 a distance 90 sufficient to provide bottom opening 11 with a cross section area at least as large as, or possibly larger than, the cross sectional area 10 of discharge tube 6, with the latter to be determined in accordance with criteria discussed below (particularly to meet the requirements of a satisfactory plastic laboratory wash bottle).

FIG. 5 illustrates in plan view how corresponding mold sections 21 and 21a are mated to provide the desired shape bottle mold. As shown, the mold may include a number of pairs of bottle mold sections to simultaneously blow mold a plurality of unitary wash bottles.

Referring now to FIGS. 91l, these respectively show initial, intermediate, and final positions of the mold sections 21 and 21a as they close around the plastic parison 29. In FIG. 9, the blow pin 22 is shown after portion 39' has been inserted within the lower portion of plastic parison 29. The mold sections 21 and 21a have not yet made any contact with the parison 29, and therefore its initial substantially cylindrical shape has not yet been distorted.

In FIG. 10, there is illustrated an intermediate position of the mold sections, wherein the edges of lands 31' and 33 which define mating recesses 50 in each of mold sections 21 and 21a, abuttable mold section faces 95, and reduced mold neck forming sections 34 are shown as making contact with the plastic parison 29 and deforming and flattening the parison.

Finally, in FIG. 11, mold sections 21 and 21a are shown in their closed positions. The general shape of the blow molded wash bottle cross section may now be seen. As shown in FIG. 11, the major part of plastic parison 29 forming the main bottle portion 5, has not yet made full contact with the sides of the mold cavities 30 to form the bottle wall 8 to final configuration of the mold; but the continuing pressure of the air supplied through passage 38 in blow pin 39 will cause full conformity of the plastic material with the surfaces of the mold cavity when the blowing process is complete. Bottle discharge tube 6 is formed within the mating recesses 50 of mold sections while the web 9 which separates the container portion 5 of the bottle 4 from the discharge tube 6 is formed in the clearance 91 between lands 33.

As shown, a certain amount of the plastic material of the parison 29 becomes flashing within the mating flash relief depressions 44 of mold sections 21 and 21a, as shown at 57, since at the lower end of the mold 21-21a the bottle spout portion 13-13 is simultaneously blow molded from this portion of the flattened parison 29 within the mating recesses 86 defined by lands 87, 88 and 89 (see especially FIG. 1).

As shown in FIG. 10, contact of portions of the plastic parison 29 with aforementioned various components 31', 33, 95 and 34, etc. of the closing mold sections 21 and 21a will unavoidably cause deformation of the plastic material, which may result in molding malfunction as the mold sections close, especially in the region of mating mold section lands 33 and 31. Hence, it is desirable to provide means for assuring that the plastic material conforms to the mold surfaces so that a properly shaped bottle discharge tube and spout may be successfully blow molded with the main bottle portion. A preferred system of achieving this is by pre-blowing the parison 29. To this end, control means are provided so that when the closing two mold sections 21 and 21a reach the position at which lands 33 and 31' forming mating bottle tube recesses 50 contact parison 29 and start to deform it, air at low pressure (e.g., 2-5 p.s.i.) is introduced through aperture 38' in blow pin 39 to force the deforming parison 29 to conform generally to the mold shape in the vicinity of mating recesses 50 formed by lands 33 and 31. Such control means may be of any convenient or desired type known in the art and customarily used for such purposes. By way of example, a limit switch 53a is affixed to mold section 21 for cooperation with a cam assembly 53b on complementary mold section 21a, as illustrated in FIG. 10. A cam 530 is positioned to deflect actuating arm 53d of limit switch 53a when mold sections 21 and 21a reach the desired degree of closure. Limit switch 53a is electrically connected to the blow mold pressure control system 53e which provides the desired pre-blow pressure to blow pin 22.

As the mold sections completely close, which closure may be determined by micro-switch means and control circuitry, the regular air pressure source for blow head 22 is opened to blow mold the plastic material, expanding it into conformity with all portions of the mold cavity, as shown in FIG. 11, and explained above, thus forming the unitary wash bottle or liquid dispenser 4.

While the use of such a pre-blow of the parison as the mold cavity is closing is not absolutely essential, it has been found that this method is highly advantageous for rapid, eificient, low cost production by eliminating malfunction, precise operational control, and product deficiency and rejects, due to the configuration of the bottle and mold apparatus, sway of parison 29, etc., thereby decreasing the unit cost of commercially suitable wash bottles produced from a given press and mold. If preblowing is used, it is necessary to properly time the application thereof in relation to the closure of the mold sections 21 and 21a, location and size of parison, and other pertinent molding conditions. In one suitable embodiment, the time for pre-blow may be approximately one second, with a relatively low pre-blow pressure in the range of approximately two to five p.s.i.; followed, upon final closure of the mold sections, by a relatively high blowing pressure, in the range of approximately 50 to 120 p.s.i., and preferably about 60 to p.s.i., for final blowing of the bottle.

It will be noted that with the above-described novel method and apparatus, the mating lands 33 forming bottle web 9 do not extend all the way to bottom lands 32, thus providing an opening at 90 (see FIG. 1) so that the main mold cavity 30 is in communication with mating recesses 50 between lands 33 and 31. Hence, the compressed air from blow pin 39 introduced into parison 29 passes from within the main portion of parison 29 in cavity 30 through opening 90 to simultaneously blow the discharge tube 6 and spout 1313' which are sealed from the main blow bottle portion 5 by web 9 compression formed between mating lands 33.

Referring now to FIGS. 16 and 17, there will now be explained the novel manner in which the relative positioning of the extruding head 20 and the mold sections 21 and 21a is determined according to the present invention.

FIG. 16 shows, in vertical sectional view, the extruding head 20, the outline of the cavity portion 30 of mold section 21 and the blow pin 22 in its non-operating vertically displaced position below the mold section 21 (and mold section 21a). Shown within the extruding annulus 27 is the plastic material 27a as it is being formed into the parison 29. As shown, the diameter D of the extruding annulus 27 is smaller than the diameter D of the extruded parison, in accordance with the known phenomenon of swell oftentimes encountered in the extrusion of polyethylene and other thermoplastic materials suitable for blow molding according to this invention. However, it should be understood that these and other materials contract or neck down rather than swell under some circumstances, which would result in a parison of diameter 9 smaller than D but would not otherwise affect the practice of this invention.

Note: For purposes of convenient explanation, the diameters D and D are taken as the average diameters of extruder annulus 27 and parison 29, respectively. Also, for illustrative examples, reference is made to low density polyethylene (LDPE) having a parison swell ratio of about 1.15. However, the swell ratio of thermoplastic materials suitable for this invention might commonly vary from 1.3 to 1.0, or even less due to neck down. (Swell ratio is commonly the ratio of outside diameter of the extruded plastic parison 29 to the inside diameter of extruder die bore 24.) The thickness 1,, of the extruded parison 29 increases in relation to the radial width W of extruder annulus 27 approximately according to this swell ratio. Thus, in practice, adjustment would be made for said average diameters D and D according to such variation of extruded parison thickness t Referring briefly to FIGS. 3, 5, and 10, it may been seen that as the mold sections 21 and 21a close around the parison 29, contact with mold section lands 31, 32, 31 and 33, and mold parts 34 and 95, will cause the plasticated parison 29 to assume a generally flat shape as shown in FIG. 10. This flattening of parison 29 is indicated in FIG. 16 by lines 29a. It should be recalled that in the process of blow molding, the mold sections 21 and 21a are closed around parison 29 and the blow pin 22 is inserted into the neck opening defined by regions 34 of the mold sections 21 and 21a. The bottle neck portion may be of any desired diameter, but the diameter of blow pin portion 39 is made of such size that when the blow pin is inserted into tubular parison 29 and the neck forming parts 34 of mold sections 21 and 21a close around portion 39, the neck portion 15 of the bottle 4 is compression molded during blow molding of the bottle itself.

The diameter of the extruding annulus 27, D and the relative positioning of the extruded parison 29 with respect to mating mold sections 21 and 21a is of course in part dependent upon the size and shape of the finished bottle. Since blow pin portion 39' is to be inserted within the parison 29, the left side 52 of extruded parison 29 should be positioned adjacent the corresponding side of reduced neck portion 34 of die sections 21 and 21a and should also be far enough toward the left side of the mold cavity to permit the side 52 of parison 29 to clear the corresponding side of blow pin portion 39'. Further, the flattened parison 29 should extend at least as far as the right-most edge 53 (in FIG. 16) beyond the mold portion 86 forming bottle spout 1313 (see also FIG. 6).

To meet the stated conditions for a mold having the right-most blowing portion at 53 extending a distance X from the left side of the neck forming portion 34 (see FIG. 16), the minimum value for the diameter D of the extruding annulus 27 should be approximately 0.70 X, using LDPE.

The positioning of the extruding head relative to the blow pin so as to assure clearance of portion 52 of the parison by the blow pin may be subject to variation depending on the configuration of blow pin portion 39'. E.g., if a tapered blow pin is used having a truncated conical configuration as shown in the drawings, the edge 52 of the parison need only be located so as to insure that the narrowest portion of the blow pin portion 39" will enter inside the lowermost section of the parison 29 since the tapered side of pin 22 tends to displace the plasticated parison 29 toward neck forming portion 34 of the mold as it is inserted, for molding of the bottle neck as shown. However, in volume production (with either a tapered or substantially cylindrical pin portion 39), it is desirable to position the extruding head so that the lower end of extruded plasticated parison 29 will be extended substantially adjacent to neck forming portion 34 as shown in FIG. 16at least when mold sections 21 and 21a are in closed position, and preferably when they are in open position-to insure clearance and to reduce malfunction which might result from reliance on lateral displacement of the parison 29 during the molding operation. The minimum operable value for D stated above (0.70 X for LDPE) is substantially independent of the shape of the blow pin, since after insertion of the pin in extruded parison 29, the latter will be positioned immediately adjacent to the mold neck forming portion 34 at the time of molding (as shown in FIG. 16); and, it is in this position that the above-stated requirement for the lateral extent of the flattened parison must be met. However, use of a tapered blow pin will permit some variation in the precise size of extruded parison 29 and the use of average diameter D of the extruding die and/or location of its axis 96 with respect to blow pin axis 97, in light of the disclosure herein.

Assuming now, an extruded parison as shown in FIG. 16, with left side substantially adjacent the neck forming opening for a given value of D optimum positioning of the extruding head 20 with relation to mating mold sections 21 and 21a to position the side 52 of parison 29 immediately adjacent the side of mold neck portion 34 will result in a displacement of the central axis 96 of the extruding head 20 with respect to the central axis 97 of the blow pin 22, and thus with respect to the bottle neck forming mold portions 34. This displacement will depend in part on the particular material used for the bottle. E.g., for LDPE, it has been found that if the left side of the bottle neck 34 (in FIG. 16) is used as a reference, the displacement A of the extruding head axis 97 (see FIG. 16) will be approximately equal to 0.58 times the diameter D of the extruding annulus 27. For a bottle made of LDPE with given dimensions establishing distance X in FIG. 16 according to the foregoing, the values of D and A indicated above determine operative conditions for the present invention, and also the optimum conditions for conservation of plastic material.

For a given value of D displacement of the axis 96 of the extrusion head 20 with respect to mold sections 21 and 21a by a distance A substantially greater than 0.58 D will result in positioning the extruded LDPE parison 29 so that its left edge will not clear the left side of the blow pin portion 39. Of course, use of a tapered blow pin will permit some variation and will also reduce somewhat the criticality of this limit, as will be apparent to those skilled in the art in light of the disclosure herein. For displacement of extrusion head 20 with respect to mold sections 21 and 21a by a distance A substantially smaller than 0.5 8 D the flattened extent L of an LDPE parison 29 will be insuflicient to provide the required material to properly form the discharge tube 6 and spout 13- 13' of a unitary blow molded bottle such as in FIG. 6. If the left end of the parison 29 is kept immediately adjacent the left side of mold neck portion 34 (per FIG. 16), and the parison diameter and displacement A of extruding head 20 are increased, then the righthand edge 29a of the flattened parison will extend beyond the right-most portion 53 of the mold and will result in unnecessary Waste of material and increased cost of manufacture.

Still referring to FIG. 16, as the diameter of extruding annulus D of head 20 is increased, the condition will be reached where the left side 54 of the flattened parison 29a will reach or extend beyond the left side 55 of mold cavity 30 (determined by mating lands 31). This will cause lands 31 to pinch the parison at this side of the mold, producing a seam in the container wall and flashing in the flash relief spaces shown at 51 in FIGS. 4 and 91l. Besides resulting in avoidable waste of material, this makes it necessary to trim and finish this portion of the bottle after it has been molded, thus significantly increasing costs, and further, the bottle wall is weakened along this line, resulting in an inferior product. Accordingly, the method and apparatus should be practiced so that flattened parison 29 does not extend to the left (at 54 in FIG. 16) beyond edge 55 of mold cavity 30 determined by mating lands 31 of die sections 21 and 21a.

Referring now to FIG. 17, it is again desirable that the flattened parison 29 not have its edge 29a extend any substantial distance beyond the right-most edge 53 of the mold cavity to avoid Waste of material. Thus, for an LDPE wash bottle with spout 13 having a maximum transverse width W per FIG. 17, the maximum desirable value for extruding annulus diameter D has been determined to be approximately 0.56 W. Again, for factors discussed with reference to FIG. 17, the placement of extruding head 20 and the axis of extruding annulus 27 with respect to the mating mold sections 21 and 21a will depend in part on the particular plastic material from which the bottle is to be made. For low density polyethylene (LDPE), it has been found that the maximum value of the distance, A between the axis 96 of extruding annulus 27 and the left-most edge 55 of the mold cavity 30 (determined by mating lands 31) should be less than approximately 0.9 times the diameter D of the extruding annulus.

Maintaining a fixed distance A between extruder axis 96 and mold cavity edge 31, and decreasing the size of extruding head diameter D will result in an insufiicient flattened parison length L to properly form the discharge tube portion 13-13 of the bottle 5; while increasing the diameter D for a fixed value A will result in flash on the left side of the bottle and weakening of the seam pinched by lands 31 when the die sections 21 and 21a close.

The above stated ranges of suitable values of D A and A have proved to have remarkable general applicability to all sorts of LDPE bottles of such configurations as defined by mold cavity 30, and to depend neither upon the actual diameter of the bottle neck, nor upon the diameter of the container nor discharge tube portions of the bottle. The only dimensions which need be fixed are the total lateral width W, and the distance X between the lefthand end of the bottle neck and the righthand end of the dispensing spout.

By way of example, the novel method and apparatus of the present invention may be used for manufacture of 4, 8, 16, and 32 oz. and other size LDPE plastic laboratory wash bottles of construction such as shown at 4 in FIG. 6.

For 16 oz. (i.e., 500 ml.) capacity bottles, approximate values for pertinent dimensions may be:

Inches Bottle height 6 Bottle body outside diameter D 3 Bottle neck diameter 1 Distance between neck and spout, X 2.5 Total extent W 3.5 Neck height 0.5

It should be recognized that thermoplastic materials other than low density polyethylene (LDPE) may be used to manufacture the blow molded unitary liquid dispensing bottles of the present invention.

In this regard, it has been found that optimum results may be achieved with any blow-moldable thermoplastic material if certain relationships between W, X, and D the diameter of the parison (shown at 29 within brackets B and B in FIGS. 16 and 17) are maintained. These relationships depend neither upon the actual diameter of the bottle neck, nor upon the diameter of the container nor discharge tube portions of the bottle, for all known suitable thermoplastic materials. The only dimensions which need be fixed are the total lateral width W, and the distance X between the lefthand end of the bottle neck and the right-hand end of the dispensing spout 53. Thus, referring to FIGS. 16 and 17, for optimum results with any suitable plastic, the relationship of the extruded parison portion 29 with respect to mating mold sections 21 and 21a (in the region of brackets B and B should be according to the following parameters:

12 (1) W=total lateral extent of the bottle (from 31 to 53), determined by desired bottle design. (2) (a). X distance from the left end of the neck opening (34) of the mold (or bottle) to the end 53 of the spout (13-13), determined by desired bottle design; provided that (b). X should not exceed about 0.8 W. (3) (a). D =average diameter of the extruded parison portion 29 (within region of brackets B and B (b). D should be at least equal to or greater than about 0.8 X; provided that (c). D should not exceed about 0.65 W.

However, generally, the relationship between the value of D and D as well as the values of A and A discussed above with reference to FIGS. 16 and 17, will depend partly on the chosen plastic material and the specific swell ratio involved, consistent with the disclosure herein.

Thus, the term plastic as used herein (and in the claims below) refers to any thermoplastic material suitable for blow-molding a unitary liquid dispensing bottle utilizing the present invention, including, without limitation, low density polyethylene (LDPE), medium density polyethylene (MDPE), high density polyethylene (HDPE), and polyvinyl chloride (PVC), which are commercially ava lable from various sources. The term low density polyethylene or LDPE refers to various forms of commercially available low density polyethylene and copolymers thereof, which may be compounded with small amounts of antioxidants, coloring agents, opacifiers, and filters, and which may have a swell ratio ranging from about 1.0 to 1.3, and usually about 1.15.

The novel molding apparatus and method of the present invention also involves certain other unique aspects as a result of the advantageous unique cross sectional configuration of blow molded unitary dispensing bottle 4 and its use as a laboratory wash bottle. For example, it has been determined that a laboratory wash bottle made of low density polyethylene resin (0.92 density) should have a minimum wall thickness t (see FIG. 7) of at least about 0.035 to 0.060 inch for the main container portion 5 and that the interior cross sectional area of the discharge tube passage 10 must be at least 0.04 square inch for satisfactory mechanical resiliency and strength and good dispensing characteristics. It also has been found that the parison wall thickness t (see FIGS. 1, 16 and 17) will be about 4.0 times the wall thickness t of the main wash bottle portion 5. The thickness of web 9 between main bottle section 5 and dispensing tube 6 (see t in FIG. 7) should be at least about 0.03; and a comparable spacing is, therefore, provided between the ends of mating web forming lands 33 (as shown especially in FIG. 11 and discussed above). Further, the radial dimension tg of web 9 (see FIG. 7) should be at least about 0.01 inch. Taking into account these factors, it has been found that irrespective of the remaining geometry of the mold 21-21a and the finished wash bottle 4, it is necessary that the operative surfaces of land 33 must be spaced from land 31 a distance d of at least about 0.20 to 0.25 inch, using low density polyethylene resin.

The above factors are further found to affect the annular Width of the extruding head 20. Assuming that a suitable wall thickness t is 0.035 inch to 0.050 inch, it is found that for low density polyethylene, a suitable minimum width W for the extruding annulus is approximately 0.08 inch.

Further, for resin other than LDPE, determination of the annular width W of the extruding head 20 and of the distance between lands 33 and 31 will depend in part on the particular plastic material chosen for the bottle and other factors consistent with the disclosure herein.

The configuration of the blow molded dispensing bottle 4 shown in FIGS. 6-8 is not only attractive in appearance, thereby increasing salability, but also results in the dispensing tube 6 being within the extended circular periphery of main container section of bottle 34, which is preferable for packing and for storage. However, unitary blow molded dispensing bottles may be molded with other configurations, using the novel methods and apparatuses of the present invention.

It is commercially advantageous to provide a modified form of the novel blow molded liquid dispenser or other container according to this invention with an integral simultaneously fabricated cap as shown in FIG. 15, to which reference is now made. A bottle according to this embodiment, generally indicated at 4a, has a main container section 5a with an integral discharge tube 6a of cross section like that shown in FIG 7; but cap 17 isconnected to part of bottle 4a by a suitable connecting strip 18, with cap 17 being designed to snap fit over lip 16a of bottle neck a to prevent loss of the cap 17. The cap 17 is fabricated concurrently with the wash bottle container portion and discharge tube, as hereafter amplified. As shown in FIG. 15, in this modified bottle 4a, neck portion 15a (and its central axis 99) is preferably laterally displaced from central axis 19 of the main bottle, portion 5a, thus achieving a significant saving of raw material in fabrication of such a blow molded bottle having an integral cap, as explained below.

In addition, the shape of bottle neck portion 15a is preferably designed to transfer vertical force applied to snap fit cap 17 on neck opening lip 16a to minimize ejection of contents of the bottle 4a due to oil can effect when cap 17 is pressed down on neck 15a. Referring to FIG. 15, this is achieved by providing neck 15a with a conical section 112 disposed at an angle y of at least about 15 degrees with adjoining neck portions 114 and 116 on either side thereof having a relatively large radius (e.g. at least /4-% inch, for the illustrative 16- ounce bottle example discussed above). Neck 15a should have a substantially cylindrical section 110 below lip 16a and above arcuate portion 114 to avoid interference when the cap 17 is snap-fitted over lip 16a.

Referring now especially to FIGS. 12, 13 and 14, there is shown a preferred form of novel apparatus for practicing the novel method of this aspect of my invention to produce a novel blow molded plastic bottle, especially of liquid dispensing type, with a unitary cap and connecting stem, and particularly wash bottle 4a of construction shown in FIG. 15.

For clarity, and to minimize duplicate description, parts in the apparatus embodiment of FIGS. 1214 which are the same as corresponding parts in the apparatus of above-discussed FIGS. 1-5, 9-11, 16 and 17, are identified with like numerals as in these prior-discussed figures; and modified parts of the apparatus of FIGS. 12-14 which are comparable to parts in the embodiment of FIGS. 1-5, 9-11, 16 and 17, are identified with like numerals as in these figures plus the letter b to the extent feasible.

FIG. 12 shows a mold section 58 which in part is the same as mold section 21, but differs from the mold section 21 by the addition thereto of another submold section 59 containing the male portion 60 of a compression molding die which is shaped to produce the desired configuration of bottle cap 17, and is constructed as below amplified with reference to FIG. 14.

FIG. 13 shows the construction of the other mating mold section 58a, which is in part the same as mold section 21a, but differing from it in that mold section 58a also includes another submold section 59a containing the female portion 60a of the compression molding die for forming integral cap 17. It should be understood that the placement of the male and female compression die sections 60 and 60a on blow mold sections 58 and 58a may be interchanged.

As shown in FIGS. 12 and 13, in order to permanently attach the molded bottle cap 17 to the bottle 4a, the female die portion 60a includes a recess 61 connecting the bottle cap forming portion of the compression die with 14 any suitable portion of the 'bottle cavity of the blow molding die section; e.g., to blow molding die recess 86- for forming the spout portion 13 of the bottle.

FIG. 14 shows the details of a preferred construction of the bottle cap compression molding apparatus, in a sectional view taken along line 1414 of FIGS. 12 and 13. As shown, the female die member 60a is suitably fixed to extended portion 59a by means such as cap screw 62 (or may be formed integrally therewith if desired). Extended compression molding section 59 which houses the male die member 60 comprises a bored cylindrical chamber 63, which contains the male die member 60 and a suitable stripping sleeve 64. Male compression molding die member 60 is fixed within the chamber 63 in such position as to project into female mold member 60a when the two mold sections 58 and 58a are united (when blow mold sections 58 and 58a are closed). Male die member 60 may be supported within the bore by means of a bolt 65 passing through bore 63 in mold section 59 and threadedly secured to die member 60 as illustrated, with a suitable bushing 66 provided to position male die member 60 within bore 63.

Stripping sleeve 64 is annular and arranged for axial motion within bore 63 along bushing 66 to assure separation of the molded cap 17 from the male die member 60 when molding is completed and the mold halves opened. Sleeve 64 has an extension 69 which normally rests against the wall 67 of bore 63 and also includes a suitably shaped cylinder section 68 whereby two reduced diameter portions indicated at 69 and 70 define two pressure chambers 71 and 72. An O-ring 73 may be positioned in a recess in the sleeve to separate the two pressure chambers. Additional O-rings 73a and 73b may be added to provide greater isolation between the chambers if needed to prevent leakage of air from one chamber to the other. Pressure inlets 74 and 75 are provided in the wall of compression die section 59 for communication with bore 63 and each of the two pressure chambers 71 and 72, respectively. The stripping sleeve 68 also contains one or more passages 76 offset from the pressure inlet 75 and in communication therewith via annular groove 101 when the stripping sleeve 64 is in engaged position at the interface between mating compression die sections 59 and 59a. Upon the separation of the mold sections 58 and 58a, compressed air from a suitable source is introduced through inlet 74 to pressure chamber 71 to move the stripping sleeve (upward in FIG. 14) to displace the compression molded cap 17 and positively separate it from the male die member 60 to which the cap 17 tends to adhere due to undercut 102 (instead of moving with female die member 60a). Upon separation of mold sections 58 and 58a, air under pressure is introduced into pressure chamber 72 through inlet 75, groove 101 and apertures 76 to return the stripping sleeve 64 to its rest position. Cooling media may also be introduced into these sections if found necessary or desirable.

For the embodiment of FIGS. 12-15, a sufiicient length of parison 29 is extruded, e.g., to mold edge 103 so that the integral cap portion 17 may be simultaneously molded beneath the spout blow molding portion 86 of the bottle blow mold sections. However, it will be recognized from the relative positioning of the blow pin 22, reduced diameter neck forming blow mold portion 34, and the spout forming portion 86 of the blow mold sections, that the compression cap molding apparatus shown in FIGS. l214 should be positioned entirely to the right of the blow pin in order to avoid interference therewith. Therefore, when it is desired to make a cap 17 having a diameter greater than the distance between the adjacent side of the bottle neck and the furthest end of the spout 13-13, it is desirable to displace neck portion 15 and its axis 99 from the bottle axis 19, as shown in FIG. 15, for a sufficient distance to permit compression molding of cap 17 of the desired size from the portion of the parison extending below spout blow molding section 86, to avoid waste of material.

Referring again to FIGS. 16 and 17, it may be seen that this involves increasing the dimension X while keeping the dimension W fixed. Thus, mating neck portions 34 of the blow mold sections may be displaced sufficiently to produce the desired integral cap 17, according to the embodiment of FIGS. 12-15, without any change in the basic requirements for either operative or optimum molding apparatus design and procedures as described in connection with FIGS 16 and 17. However, if the distance X is so increased as to place the bottle neck forming mold portion less than a certain distance from the lefthand wall of the bottle as shown in FIG. 17, then it will no longer be possible to position the blow mold sections with respect to the extruding head 20 so as to assure insertion of portion 39' of the blow pin 22 within parison 29, while avoiding production of rfiash to the left of the bottle wall (per FIGS. 16 'and 17). For a particular diameter of bottle neck 15a, and bottle width W, it has been determined that a limiting value of X is approximately 0.81 W. Beyond this, in order to increase the available area for simultaneous compression molding of the cap 17, it is necessary to decrease the diameter of the neck forming portion 34 of the blow mold sections (and thus of bottle neck 15a).

While specific embodiments of this invention have been described in detail, it should be recognized that substantial departure from the specific details shown is possible within the scope of this invention. For example, the shape of the desired bottle, and therefore the particular configuration of blow mold cavities 30 of die sections 21 and 21a (and 58 and 58a) are subject to wide variation in accordance with the intended use of the bottle. While the bottles of FIGS. 6 and 15 have been shown as having the discharge tube portions thereof formed within the periphery of the main container portion, which is preferable, as discussed above, this placement may be varied with variation accordingly of both dimensions X and W of FIGS. 16 and 17.

The particular configuration of cap 17 shown in FIGS. 12-15 is of course subject to variation, as is the particular type and position of the attaching link 61 between the cap 17 and the bottle 4a. In fact, it may be desirable under certain circumstances to mold the bottle and cap concurrently as shown, but without any attached link between them such as 61.

It is also possible to use the method and apparatus inventions of FIGS. 12-14 to make a conventional blow molded bottle and connected compression mold cap as shown, but without the integral discharge tube utilized for making a liquid dispensing bottle, by elimination of land 33 and associate spout forming portions 86-89 (see FIG. 1) and joining land 31' to the adjacent land portion at the side of neck forming section 34 (i.e., making side land 31' like side land 31). The manner of doing this will be apparent to those skilled in the art in light of the disclosure herein, whereby further amplification is deemed unnecessary.

The precise nature of the male die member and stripping sleeve, etc. is subject to variation from that shown in FIG. 14. For example, instead of an upper air pressure chamber 72 and associate conduit 75, 101, 76 for returning the-stripping sleeve 64 to rest position, there may be provided spring biasing or like mechanical means to return stripping sleeve 64 to its rest position in the absence of air pressure in the lower pressure chamber 71.

In the event it is desired that the blow molded wash bottle have a screw threaded neck for a screw on cap instead of a snap ring for cap as shown at 15' in FIG. 15, neck forming portions 34 of mold sections 21 and 21a may be appropriately modified to compression mold a screw threaded bottle neck in a manner which will be apparent to those skilled in the art in light of the disclosure herein.

In the following claims, various relationships of significance in defining the invention are stated in terms of di- 16 mensions shown in FIGS. 16 and 17. Therefore, it is to be understood that the terms, W, X, A A D D etc., are used in accordance with the definitions thereof given in the specification in explanation of FIGS. 16 and 17 and are to have the meanings there stated.

Various other modifications are contemplated and may obviously be resorted to by those skilled in the art without departing from the spirit and scope of the invention as hereafter defined in the appended claims.

What is claimed is:

1. A blow mold for forming, from a tubular parison, a plastic container having a body, a filling opening, and an integral closure for the filling opening comprising: a pair of mold sections engageable to form a hollow cavity corresponding to the shape of the container, a passage at one end of the cavity to mold said filling opening, and one portion of a compression molding die on each mold section for forming the removable closure for said filling opening out of an otherwise wasted portion of the parison concurrently with the molding of the container, said die being longitudinally spaced from said cavity but substantially within the periphery thereof, the longitudinal axis of said die portions being disposed in non-parallel relationship to the longitudinal axis of the hollow cavity, at least one of said compression molding die portions being connected to said hollow cavity by a narrow channel for receiving therein a portion of the parison to form a connecting strip of plastic between the compression molded cap and the blow molded container.

2. A blow mold as defined in claim 1 wherein said cavity is bounded by a plurality of lands having the desired configuration to form the outline of said container, said plurality of lands including first and second lands defining side walls for said cavity, and a third land defining a further cavity Wall to form a closed bottom for the container, segments of the first and second lands defining said passage to mold said filling opening for the container.

3. A blow mold as defined in claim 1 wherein the longitudinal axis of the compression molding die is disposed in perpendicular but non-intersecting relationship to the longitudinal axis of said cavity.

'4. A blow mold as defined in claim 1 wherein said passage for molding said filling opening is displaced from the longitudinal axis of the mold cavity and wherein said compression molding die portions for molding said closure are partially situated in the area vacated by said displacement.

5. A blow molding machine for forming a container having a body, a filling opening, and an integral closure for said filling opening comprising: a blow mold having a pair of mold sections as defined in claim 1; an extruding head for forming a tubular parison of plasticated material; said pair of mold sections being positioned for closure around the extruded parison; and blowing means positioned for insertion into the passage for molding said filling opening; said extruding head being so positioned relative to the mold and blowing means that upon extrusion of a parison and closure of the mold, a portion of the parison occupies the passage for molding said filling opening with the blowing means disposed within the parison.

6. A blow molding machine as defined in claim 5 wherein said cavity is bounded by a plurality of lands having the desired configuration to form the outline of the container, said plurality of lands including first and second lands defining side walls for said cavity, and a third land defining a further cavity wall to form a closed bottom for the container, said first and second lands including elongated portions defining said passage for molding said filling opening, the wall of said passage and the blowing means being of such size and configuration relative to each other as to cooperate to compression mold a neck for the container.

7. A blow molding machine as defined in claim 6 wherein the wall of said mold passage includes means for molding a peripheral lip on the neck of the container and 17 18 where said compression molding die includes means for 3,317,955 5/1967 Schurman et a1. 185 molding a portion on said cap to engage with said lip on 3,342,916 9/1967 Peters 18-5 X the container neck. 3,359,602 12/ 1967 Bailey 185 References Cited UNITED STATES PATENTS 5 WILBUR L. McBAY, Primary Examiner 2,778,533 1/1957 Savary.

3,050,773 8/1962 Hagen l85 X 3,159,697 12/1964 TOcCi 18-5 X 18-35;26494, 98

3,278,666 10/1966 Donald 185 X 

